Anatomy and Physiology 12: DNA and Gene Expression Unit PDF

Summary

This document discusses DNA cloning, sequencing, and analysis, including polymerase chain reaction (PCR) and Sanger sequencing. It also touches on the human genome project and its implications.

Full Transcript

**Anatomy and Physiology 12 : DNA and Gene Expression Unit**

**Clonging/Sequencing/Analyzing DNA**

Who here likes crime shows? Paternity testing drama? Do you know what
types of methods they use to catch suspects?

-usually we hear lots about PCR -- polymerase chain reaction

History of DNA sequencing and cloning

-Kary Mullis invented PCR in 1983 (relatively recent discovery) and won
a nobel prize-- revolutionary because we weren't able to acquire large
quantities of specific sequences of DNA prior -- enabled scientists to
identify genes and connect them to diseases, do forensic/paternity
testing

-my old biology professor used to talk about Mullis being strange --
believes climate change isn't related to human activity, HIV doesn't
cause AIDS, and used to cause personal conflicts with coworkers

Old cloning methods use bacteria -- see page 129 in your textbook -- we
will get there soon when we would do that

**Modern Cloning - Polymerase Chain Reaction (PCR**) -- make millions of
copies of a specific DNA sequence

Youtube: https://www.youtube.com/watch?v=a5jmdh9AnS4&t=273s

Need 3 things:

Taq polymerase -- a heat stable version of DNA polymerase

2 Oligonucleotide (short section of nucleotides) Primers -- act like
pieces of bread that sandwich the DNA sequence of interest

Lots of A,T,G,C nucleotides for building DNA copies

**PCR 3 basic Steps:**

1. [Denature] the DNA helix into two separate strands using
high heat

2. Let the two oligonucleotide primers [anneal]

3. Taq polymerase extends off the primers until it reaches the end of
the DNA strand

Benefits of PCR? -- only need a really small sample, and it is entirely
what you want

**How can we use PCR for forensics?**

- Recall that we are [diploid] organisms -- we have 23
chromosomes and there are 2 copies of each

- Our DNA has some [conserved] (found in everyone)
sections of DNA -- one example of these are [short tandem
repeats] (STR's) -- short sequences of DNA that repeat
(1-6 base pairs long)

- However, there are slight variations of the number of repeats people
have

- We can use PCR to amplify these sections, then run the DNA using gel
electrophoresis to separate out the different size pieces -- will
appear as dark bands on the gel

-gel electrophoresis uses electrical current to push DNA through
small pores in the gel -- larger fragments get stuck and travel less
distance

- How many bands would you see if you were homozygous? (1)
Heterozygous? (2)


In practice, we would sample multiple STR locations, so that you would
see a bunch of bands -- see electrophoresis gel below

**Now we know how to clone DNA -- how do we determine which nucleotide
is where in a sequence?**

[Sanger Sequencing] or **[Chain
Termination]** Sequencing

https://www.youtube.com/watch?v=dVRB4CaLizc

- Follows the same general process as PCR, except that fluorescently
labelled dideoxynucleotides are included (different label for each
base) -these nucleotides are missing the 3' oxygen needed to form
additional phosphodiester bonds -- DNA synthesis stops

-eventually you will have a whole bunch of labelled DNA strands
differing in length by 1 nucleotide

- Capillary gel electrophoresis separates the fragments by size --
computer detector reads fluorescence passing by -- tells us the
sequence

- Many other next generation methods on the way

**Human Genome Project was enabled by these recent technological
developments**

- 13 year project -- started in 1990 and ended in 2003

- Our entire genome has been sequenced -- how does this help us?

-see single nucleotide polymorphisms (SNP's) between individuals --
related to disease?

-we have 25,000 genes and a ton of non-coding DNA -- what is its
purpose?